Equilibrium Elasticity of Diblock Copolymer Micellar Lattice

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Macromolecules 2001, 34, 662-665

Equilibrium Elasticity of Diblock Copolymer Micellar Lattice Hiroshi Watanabe,*,† Toshiji Kanaya,† and Yoshiaki Takahashi‡ Institute for Chemical Research, Kyoto University, Uji, Kyoto 611, Japan; and Center for Integrated Research in Science and Engineering, Nagoya University, Nagoya, Aichi 464-8603, Japan Received May 23, 2000

I. Introduction Styrene-butadiene (SB) diblock copolymers form spherical micelles with S cores and B corona in a B-selective solvent, n-tetradecane (C14). In moderately concentrated solutions where the corona B blocks of neighboring micelles are overlapping each other, these micelles form cubic lattices because of the thermodynamic requirements for the corona B blocks:1-4 Each corona block is required to randomize its conformation so as to increase the conformational entropy. At the same time, neighboring corona B blocks are osmotically required to have mutually correlated and constrained conformations (with small entropies) so as to minimize the concentration variation in the B/C14 matrix phase and reduce the osmotic free energy. The micellar lattice is formed as a structure that compromises these contradicting requirements. In fact, the lattice is disordered in a polymeric B-selective solvent (homopolybutadiene) that screens the osmotic requirement and allows the corona blocks to randomize their conformations without violating the osmotic requirement.3,4 The SB/C14 micellar lattices exhibit equilibrium elasticity against small strains.1-4 The equilibrium modulus Ge, representing the thermodynamic stability of the lattice,4 was measured at 25 °C for SB/C14 solutions having various S and B molecular weights (MS and MB) and/or various concentrations (c).1,2 In Figure 1, those Ge data1,2 are normalized by the thermal energy kT (k ) Boltzmann constant and T ) absolute temperature) and plotted against the number density ν of the corona B blocks in the solution (unfilled symbols). Ge of those well developed micellar lattices (having various MS, MB, and c) are almost proportional to ν, as already pointed out in the previous study.4 This result suggests that the osmotically constrained corona blocks entropically sustain the equilibrium elasticity.4 Since each corona block tethered on the S core has the free end, kinetic effects (such as entanglements) relax/disappear in long time scales where Ge is evaluated. Thus, in the simplest case of the entropic elasticity, each corona block behaves as an independent stress sustaining unit (entropic strand) and its contribution to Ge is given by kT. In Figure 1, the dashed line indicates the equilibrium modulus Geo expected for this case

Geo ) νkT

(1)

Clearly, the measured Ge is smaller than this Geo by a * To whom correspondence should be addressed. † Kyoto University. ‡ Nagoya University.

Figure 1. Plots of normalized equilibrium modulus Ge/kT (kT ) thermal energy) of SB micellar lattice in n-tetradecane (C14) against the number density ν of the corona B blocks. Squares indicate the data previously obtained for SB 16-36/C14 solutions with c ) 20, 30, and 35 wt %1 and the triangles, the data for 10 wt % solutions of SB 20-46, 20-100, 32-102, 32160, and 32-262,2 where the sample code numbers indicate 10-3MS-10-3MB. The filled circle represents the data of the 15 wt % SB 11-23/C14 solution obtained in this study. All SB micellar lattices were prepared by quiescently cooling the disordered solutions (from T > TODT to 25 °C) and had the polycrystalline structure. The dashed line indicates the equilibrium modulus expected for the simplest case of entropic elasticity of the corona blocks, Geo ) νkT.

factor of ∼10. (If we consider the filler effect,5 the expected Geo is larger than that given by eq 1 and the difference from the measured Ge is more prominent.) The SB micellar lattices examined in Figure 1 were prepared by quiescently cooling the disordered SB/C14 solutions at high temperatures (T > TODT). These lattices unavoidably had polycrystalline structures with many defects, and the above puzzling difference of Ge and Geo was vaguely surmised to reflect an effect of the defects.4 However, no further detail of the difference was discussed in the previous studies.1-4 We can examine this difference with the aid of the shear-orientation technique that has been applied to colloidal crystals6 as well as block copolymers in bulk7-12 and in micellar solutions.13-16 The shear-orientated micellar lattice should include less defects compared to the quiescently ordered lattice. If the defects are the main factor raising the above difference between Ge and Geo, Ge should increase significantly on the shearorientation. With the above strategy, we followed McConnell et al.15 to shear-orient a micellar lattice of a model SB copolymer in C14. Surprisingly, we found that the shear-orientation hardly affects the Ge value and thus the defects are not the main factor raising the difference between Ge and Geo. This fact led us to relate this difference to the osmotically induced conformational correlation of neighboring corona B blocks. Details of these results are described in this article. II. Experimental Section Material. A styrene-butadiene (SB) diblock copolymer composed of deuterated S and protonated B blocks was synthesized via sequential living anionic polymerization in benzene. The initiator, sec-butyllithium, was synthesized from lithium metal and sec-butyl bromide (both purchased from Aldrich). The monomers were purified with triphenylmethyl-

10.1021/ma000897k CCC: $20.00 © 2001 American Chemical Society Published on Web 01/05/2001

Macromolecules, Vol. 34, No. 3, 2001

Notes

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Table 1. Characteristics of SB Copolymera code

10-3MSb

10-3MBc

Mw/Mnd

SB 11-23

11.1

23.0

1.04

a

Composed of deuterated S and protonated B blocks. b Determined from GPC elution calibration for the precursor S block after correction of the difference of the monomer molecular weights for deuterated and protonated S. (Mw/Mn ) 1.03 for the S block.) c Evaluated from M of the S block and the B weight fraction in S the copolymer, with the latter being determined from RI and UV signals. d Evaluated from GPC elution calibration for the copolymer.

lithium (for S from Aldrich) and sec-butyllithium (for B from Tokyo Kasei). The SB copolymer and its precursor S block (recovered before the copolymerization of the B block) were characterized with GPC (CO-8020 and DP-8020, Tosoh) equipped with refractive index (RI) and ultraviolet adsorption (UV) monitors (LS-8000 and UV-8020, Tosoh) connected in series. Monodisperse polystyrenes (Tosoh TSK’s) were utilized as elution standards. Table 1 summarizes the characteristics of the SB sample (coded as SB 11-23). The system examined was a SB 11-23 solution in n-tetradecane (C14). This solution was prepared from a homogeneous solution of SB 11-23 and C14 in excess benzene by allowing benzene to thoroughly evaporate. The SB concentration in the SB/C14 solution, determined after this evaporation, was 15 wt %. In this solution at 25 °C, spherical micelles with glassy S cores and solvated B corona formed the bcc lattice, as noted from the small-angle neutron scattering (SANS) profile shown later. Measurements. For the 15 wt % SB 11-23/C14 solution at 25 °C, rheological measurements were carried out with a laboratory rheometer (RMS605, Rheometrics). A Couette flow cell with radii of the inner and outer cylinders, ri ) 25.0 mm and ro ) 26.0 mm, respectively, was utilized (so that the flow geometry was similar to that in shear-SANS measurements). In SANS measurements, we utilized the SANS-U beam line at the Neutron Scattering Laboratory, Institute for Solid State Physics, University of Tokyo (Tokai, Ibaragi, Japan) in the following configuration: incident neutron wavelength λ ) 0.7 nm, wavelength spread ∆λ/λ ) 0.1, sample-to-detector distance ) 4.00 m, and beam diameter ) 0.3 cm. The scattering intensity was measured as a function of the scattering vector q, where q ) |q| ) [4π/λ] sin(θ/2), with θ being the scattering angle. The SANS measurements were carried out at room temperature (=25 °C) for the SB 11-23/C14 solution in a Couette flow cell17 with ri ) 25.25 mm and ro ) 27.00 mm. For the quiescently ordered solution (prepared by cooling the solution from T > TODT to 25 °C), the SANS profiles were obtained before, during, and after imposition of the steady shear flow. The incident beam was in the direction normal to the surfaces of the inner/outer cylinders of the cell (i.e, in the direction of the velocity gradient), and the profiles were detected in a velocity-vorticity (x-y) plane. (Thus, the total sample thickness for the scattering was 3.5 mm.) With the above configuration, the scattering was detected in a range of qx and qy, |qx| e 0.71 nm-1 and |qy| e 0.71 nm-1. No correction was made for the incoherent scattering.

III. Results and Discussion III-1. Shear Orientation. For the face- and bodycentered cubic (fcc and bcc) lattices of styrene-isoprene (SI) diblock copolymer micelles in n-decane (C10; Iselective solvent), McConnell et al.15 examined SANS profiles during flow at various shear rates γ˘ . They found that the long-range order of both lattices change with γ˘ and these changes (of the fcc lattice) are correlated with the quasi-stationary shear stress σ.15 We attempted to

Figure 2. Flow behavior of the 15 wt % SB 11-23/C14 solution at 25 °C. The unfilled and filled symbols indicate the quasi-stationary shear stress measured for increasing and decreasing γ˘ , respectively.

utilize their results as a clue to find the optimum γ˘ value for achieving the long-range order in our SB micellar lattice. For this purpose, we followed McConnell et al.15 to examine the flow behavior of our SB 11-23/C14 solution. The results are shown in Figure 2. The unfilled and filled symbols indicate the quasi-stationary σ data obtained for increasing and decreasing γ˘ , respectively. The hysteresis, seen for these two sets of σ data at γ˘ < 20 s-1, disappears at higher γ˘ . With decreasing γ˘ , σ decreases significantly in the nonhysteresis regime and less prominently in the hysteresis regime. These features are similar to those found for the fcc-type SI micellar solution,15 (although this SI solution also exhibited small but abrupt drops of σ that are not observed for our bcc-type SB micellar solution). The fcc lattice of the SI micelles examined by McConnel et al.15 appears to be best oriented at γ˘ a little smaller than the threshold γ˘ value between the hysteresis and nonhysteresis regimes. The threshold for our bcc-type SB micellar lattice is at γ˘ ∼ 20 s-1 (Figure 2). Thus, we chose γ˘ ) 10 s-1 and examined the shearorientation of our SB lattice at this γ˘ . The results are shown in Figure 3. The panels show the SANS profiles each obtained with the exposure time of 10 min. The horizontal and vertical (x and y) directions correspond to the velocity and vorticity directions of the shear flow. The quiescently ordered SB micellar lattice was prepared in the SANS flow cell by cooling the 15 wt % SB 11-23/C14 solution from high T (>TODT) to 25 °C. Essentially isotropic scattering peaks are observed at q ) 0.22, 0.32, and 0.38 nm-1; cf. the left panel of Figure 3. (The stronger scattering in the x direction results from a weak lattice orientation due to the sample shrinkage in the cell on cooling.) The ratio of these q values is very close to 1:x2:x3. These results indicate that the quiescently ordered solution has the isotropically orientated bcc polycrystalline structure (with the lattice spacing D = 35 nm). This polycrystalline structure should include many defects. Under the steady shear at γ˘ ) 10 s-1, the scattering pattern drastically changes to the anisotropic pattern (middle panel of Figure 3). A similar pattern was found for the bcc-type SI micellar lattice under flow and assigned as the scattering from the locally distorted 〈110〉 plane.15 The long-range order of the SB lattice (reflected in the pattern anisotropy) is enhanced when the solution is kept quiescently after cessation of the steady shear, as seen in the right panel of Figure 3 (obtained 50 min after the cessation). Thus, the orien-

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Macromolecules, Vol. 34, No. 3, 2001

Figure 3. SANS profiles of the 15 wt % SB 11-23/C14 solution at 25 °C. The quiescently ordered SB micellar lattice has the polycrystalline bcc structure (left panel). This lattice is oriented under steady shear flow at γ˘ ) 10 s-1 (middle panel), and the long-range order of this lattice is enhanced when the solution is quiescently kept for 50 min after cessation of the shear (right panel). Each profile, covering |qx| e 0.71 nm-1 and |qy| e 0.71 nm-1, was obtained with an exposure time of 10 min.

tated SB lattice with less defects was successfully obtained after the shear at γ˘ ) 10 s-1. We also examined different γ˘ values but obtained less orientated SB micellar lattice. In particular, the shearmelting occurred under the flow at high γ˘ ()100 s-1), as similar to the result reported for the bcc-type SI micelles.15 Thus, the shear at γ˘ ) 10 s-1 gave the best orientated SB micellar lattice that quite possibly included the smallest amount of defects. III-2. Equilibrium Modulus of SB Micellar Lattices. On the basis of the above SANS results, we compared the linear viscoelastic responses of the quiescently ordered bcc polycrystalline lattice with those of the best orientated bcc lattice obtained after the steady shear at γ˘ ) 10 s-1. These two lattices were prepared in the Couette cell of the rheometer under the conditions/treatments very similar to those in the flowSANS experiments. Specifically, the viscoelastic measurement for the oriented lattice was started 50 min after cessation of the steady shear and completed in 10 min (the exposure time for the SANS profile). Thus, the rheologically examined lattices should have been very similar to those detected in the SANS profiles (left and right panels of Figure 3). Figure 4 shows plots of the storage moduli G′ of the above two lattices against the angular frequency ω of the oscillatory strain. Filled squares and unfilled circles indicate G′ of the quiescently ordered (polycrystalline) and shear-oriented lattices, respectively. G′ is insensitive to ω (